System for the Construction of a Dental Prosthesis

ABSTRACT

Method and system for the construction of a total dental prosthesis, wherein the shapes of the upper and lower jaw bases taken in the plastic material are digitized and stored as a digital prosthesis model in a data-processing device, and the upper and lower jaw prosthesis bases are produced from dental materials according to the digital prosthesis model by ablative or constructive methods.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of U.S. application Ser.No. 14/652,622, filed Jun. 16, 2015, which is a National Stageapplication of International patent application PCT/EP2013/074768 filedon Nov. 26, 2013, which claims priority to European patent applicationNo. 12197441.4 filed on Dec. 17, 2012, the disclosures of which areincorporated herein by reference in their entirety.

The invention relates to a method for the construction of a dentalprosthesis, wherein the shapes of upper and lower jaw bases are takenwith plastic material using standard impression trays or individualizedimpression trays, which have been produced in a manner individuallyadapted to the patient's jaw on the basis of prior acquisition of theshapes using standard impression trays or by acquiring the shapes bydigital scanning and/or phototechnical acquisition, when taking theshapes of the upper and lower jaw bases, the position of the occlusalplane relative to the upper and lower jaw bases is acquired with a bitefork by alignment parallel to the bipupillar line and the Camper planeand is digitally stored, the shapes of the upper and lower jaw basestaken in the plastic material are digitized and stored as a digitalprosthesis model in a data-processing device, the upper and lower jawprosthesis bases are produced from dental materials according to thedigital prosthesis model by ablative or constructive methods.

The invention furthermore relates to a system for the construction of atotal dental prosthesis, having standard impression trays orindividualized impression trays for taking the shapes of upper and lowerjaw bases with plastic material, the individualized impression trayshaving been produced in a manner individually adapted to the patient'sjaw on the basis of prior acquisition of the shapes using standardimpression trays or by acquiring the shapes by digital scanning and/orphototechnical acquisition,

a bite fork for acquiring the position of the occlusal plane byalignment parallel to the bipupillar line and the Camper plane whentaking the shapes of the upper and lower jaw bases, and a memory forstoring the digitized position of the occlusal plane relative to theupper and lower jaw bases,

a sampling device for acquiring and digitizing the shapes of the upperand lower jaw bases taken in the plastic material,

a data-processing device for storing the digitized shapes of the upperand lower jaw bases as a digital prosthesis model,

a manufacturing apparatus for producing the upper and lower jawprosthesis bases from dental materials according to the digitalprosthesis model by ablative or constructive methods under the controlof the data-processing device.

An early method and system in this direction is known, for example, fromthe article “CAD and CAM—Möglichkeiten der Optimierung in derTotalprothetik” [CAD and CAM—possibilities of optimization in totalprosthetics], Wolfgang Becker, which was published in two parts inQuintessenz Zahntechnik 17, 397-404 (1991) and 511-519 (1991). It isproposed therein to acquire the shapes of the upper and lower jaw basesphototechnically, and to generate a digital model of the upper and lowerjaw bases therefrom. These data are used in a subsequentcomputer-controlled milling process in order to produce the upper andlower jaw prosthesis bases.

A method is known from WO 2012/061652 A2. In this known method, theshapes of the upper and lower jaw bases are taken as impressions in theplastic material with standard impression trays or with individualizedimpression trays. Here, the term individualized impression trays refersto ones which have been obtained on the basis of prior acquisition ofthe shapes of the upper jaw and lower jaw, and which are thus alreadyindividually adapted to the specific anatomy of the patient. During,before or after the impression, various anatomical data of the patientmay be recorded, and for example the position of the occlusal planerelative to the upper and lower jaw bases may be determined and stored.In a system actually proposed by the Applicant, templates of a frontdental arch are also used, the position of which with respect to theimpression trays is marked by application onto the impression tray. Theposition of the front dental arch template is also digitized during thedigital sampling of the upper and lower jaw bases taken in the plasticmaterial, and is thus included in the digital prosthesis model.

A very similar computer implemented method is known from WO 2012/061655A2 which method, besides the above described steps, designs or selectsteeth by applying a number of predetermined rules, which teeth are bestmatching to a particular jaw base. The teeth may for example be selectedfrom a library including a plurality of stored teeth.

It is an object of the present invention to provide an improved methodand an improved system for the construction of a dental prosthesis, inwhich a digital prosthesis model with improved positioning of the toothinstallation can be generated. A more expedient selection of an optimalfront dental arch for the prosthesis is furthermore intended to be madepossible.

This object is achieved by the method having the features of appendedclaims and by the system having the features of the appended claims.Advantageous embodiments are specified in the dependent claims.

In the method according to the invention, a set of upper or lowerstandard front dental arches is provided, the set containing standardfront dental arches with different front tooth sizes and front toothshapes. For each front dental arch in the set of standard front dentalarches provided, their shape data which represent a three-dimensionalspatial description of the teeth of the front dental arch are stored ina database. When taking the shapes of the upper and lower jaw bases withplastic material in the impression trays, a front dental arch which bestmatches the situation in the patient's jaw is selected from the set ofstandard front dental arches provided. This selected standard frontdental arch is then positioned on the impression tray, so that itobtains the desired position in the jaw, and is fastened in thisposition on the impression tray. In order to form a starting point forthe digital prosthesis model, the shapes of the upper and lower jawbases taken in the plastic material in the impression trays with thefront dental arch fastened on one of the impression trays are digitizedby scanning in a registered bite position and are stored. From thedatabase with the front dental arch shape data of the set of standardfront dental arches, the front dental arch shape data which belong tothe selected standard front dental arch are then called up. These arethen spatially positioned in the digital prosthesis model in such a waythat there is the least possible deviation with respect to the positionof the actually scanned selected front dental arch fastened on theimpression tray. In other words, the position of the imported frontdental arch shape data of the selected standard front dental arch in thedigital spatial model of the prosthesis is varied by displacement andturning until a minimum deviation is achieved relative to the scannedfront dental arch.

In this way, when impressing the shapes of the upper and lower jawbases, it is possible for the dental technician or dental surgeon to trydifferent ones from a provided set of standard front dental arches andselect one which is most suitable. This is then fastened in its desiredposition on the impression tray, so that its future position in thedigital prosthesis model can be established. A higher accuracy of thedigital prosthesis model is made possible by importing the standardfront dental arch shape data of the selected standard front dental archfrom the database.

The method may for example be carried out by a dental surgeon or dentaltechnician, who carries out the impressions and produces the impressiontrays with the shapes of the upper and lower jaw bases taken in theplastic material and the front dental arch fastened thereon in aregistered bite position. The impression trays with the shapes takenthereon and the front dental arches fastened thereon may then be takento a dental laboratory where this shape is digitized by scanning andstored, in order to form a starting point for the digital prosthesismodel. In the dental laboratory, the digital prosthesis model may thenbe automatically completed in the data-processing device by calling upshape data for standard front dental arches and premolar tooth rows, andalso interactively gradually improved by the user by inputs and furthershapings. The final digital prosthesis model obtained in this way may,for example, then be used in a CAM method for milling the prosthesisbases from plastic blocks.

In a preferred embodiment, the data-processing device may be adapted tocall up an antagonist standard front dental arch matching the selectedstandard front dental arch for the upper or lower jaw in the form ofdigital antagonist standard front dental arch shape data from thedatabase and position it with the data of the associated jaw base in thedigital prosthesis model, in such a way that an optimal position withrespect to the selected standard front dental arch is achieved, theshape data of which have already previously been integrated from thedatabase into the digital prosthesis model.

In another preferred embodiment, after integration of the standard fronttooth shape data and optionally antagonist standard front tooth shapedata with the digitized data of the associated jaw base, one or morepremolar tooth rows matching the front dental arch are automaticallyoffered for selection by the data-processing device and, after selectionby the user, digital premolar tooth row shape data describing these arecalled up from the database and subsequently entered with the digitizedjaw base data into the digital prosthesis model in a manner matching thealready integrated standard front dental arch shape data.

In a preferred embodiment, the data-processing device generates agraphical representation of the digital prosthesis model and shows it ona screen. The data-processing device provides program functions, withwhich the digital prosthesis model can be manipulated by acting on thegraphical representation. In particular, a digital wax knife is providedas a program function, in order to configure the design of the gum andthe prosthesis base surfaces with the digital wax knife in the graphicalrepresentation of the digital prosthesis model and to transfer theconfigurations carried out in this way into the digital prosthesismodel.

In a preferred embodiment, the data-processing device provides amultiplicity of predetermined surface textures for selection, which canbe applied after selection to desired regions of the surfaces of thedigital prosthesis model.

In a preferred embodiment, at least one gingiva parameter is called upfor specification by the data-processing device. This is at least one ofthe following gingiva parameters: gingival frame of the tooth lengths ofthe installed teeth (i.e. the depth to which the tooth base extends intothe cavity in the prosthesis base), minimum wall thickness of upper andlower jaw bases (i.e. a minimum thickness which the prosthesis base musthave at each point), surface texture parameters of the palate surfaceand geometrical parameters of the transition region from the prosthesisbody to the tooth (i.e. the inner wall of the cavity need not merge witha sharp edge into the adjacent prosthesis base surface above, but ratherthe transition region may be rounded); these entered gingiva geometricalparameters are transferred into the digital prosthesis model.

In a preferred embodiment, at least one tooth cavity parameter is calledup by the data-processing device for specification, to which the widthof the adhesive gap between the inner wall of the tooth cavity and theinserted tooth base and the position and number of spacers on the innerwall of the tooth cavity, with which the tooth base is held while beingpositioned in a defined way in the tooth cavity, in order to ensure anadhesive gap with the desired width between the inner walls of the toothcavity and the tooth base everywhere, belong; the specified tooth cavityparameters for all tooth cavities are transferred into the digitalprosthesis model.

In a preferred embodiment, when, during the calculation of the cavitiesfor prefabricated plastic teeth, it is established that the remainingwall thickness of the prosthesis base below the cavity would fall belowa predetermined minimum wall thickness, the length to which the plastictooth is to be reduced in order to obtain the predetermined minimum wallthickness below the cavity is calculated and stored in thedata-processing device. The cavity is then stored in the digitalprosthesis model having been adapted to the reduced length of theplastic tooth. Furthermore, the plastic tooth is shortened to the storedreduced length of the plastic tooth in a milling device under thecontrol of the data-processing device.

In a preferred embodiment, the data-processing device provides aselection menu for artificial teeth made of different material types, inwhich a material selection from dental materials is possible for eachtooth position. Possible dental materials are PMMA, composite, zirconiumdioxide, lithium disilicate and dental ceramic. In the data-processingdevice, the selected material type is then stored in the digitalprosthesis model.

In a preferred embodiment, a bite fork which has an inner bite arch andan outer arch applied thereon using articulations is used fordetermining the position of the occlusal plane. The inner arch isintroduced between the standard impression trays or the individualizedimpression trays. Selectively, the bite fork may be fastened on theupper and/or lower impression tray by means of an interface. The outerarch is then adjusted parallel to the Camper plane and parallel to thebipupillar line by turning the articulations. The resulting deviationsof the parallelism of the inner bite arch from the aligned outer archare read from a scale on the articulations and stored.

The invention furthermore relates to a system for the construction of atotal dental prosthesis, having

standard impression trays or individualized impression trays for takingthe shapes of upper and lower jaw bases with plastic material, theindividualized impression trays having been produced in a mannerindividually adapted to the patient's jaw on the basis of prioracquisition of the shapes using standard impression trays or byacquiring the shapes by digital scanning and/or phototechnicalacquisition,

a bite fork for acquiring the position of the occlusal plane byalignment parallel to the bipupillar line and the Camper plane whentaking the shapes of the upper and lower jaw bases, and a memory forstoring the digitized position of the occlusal plane relative to theupper and lower jaw bases,

a sampling device for acquiring and digitizing the shapes of the upperand lower jaw bases taken in the plastic material, a data-processingdevice for storing the digitized shapes of the upper and lower jaw basesas a digital prosthesis model,

a manufacturing apparatus for producing the upper and lower jawprosthesis bases from dental materials according to the digitalprosthesis model by ablative or constructive methods under the controlof the data-processing device,

characterized in that

a set of upper or lower standard front dental arches is provided forselection and means are provided for fastening a selected standard frontdental arch in the desired position on the impression tray with theupper or lower jaw base impressed therein in the plastic material,

in order to form a starting point for the digital prosthesis model, thesampling device is adapted to digitize and store the shapes of the upperand lower jaw bases taken in the plastic material in the impressiontrays with the front dental arch fastened on one of the impression traysin a registered bite position by scanning,

the data-processing device is adapted to call up the standard frontdental arch shape data describing the selected standard front dentalarch from a database, which contains digital standard front dental archshape data for all standard front dental arches, and to integrate themwith the data of the associated jaw base in the digital prosthesismodel, in such a way that the position of the digital standard frontdental arch shape data relative to the digitized jaw base datacorresponds as well as possible to the position of the standard frontdental arch, fastened on the impression tray, relative to the impressedjaw base.

In a preferred embodiment of the system, the data-processing device isadapted, for the selected standard front dental arch for the upper orlower jaw, to call up a matching antagonist standard front dental archfrom the database in the form of digital antagonist front dental archshape data and introduce it into the digital model of the associated jawbase in the digital prosthesis model, in such a way that an optimalmatch with the selected standard front dental arch is achieved.

In a preferred embodiment of the system, the data-processing device isadapted, after integration of the standard front dental arch shape dataand optionally antagonist standard front dental arch shape data into thedigital prosthesis model, to offer one or more premolar tooth rowscharacterized so as to match the selected standard front dental arch forselection. After selection of the corresponding digital premolar toothrow shape data called up from the database, these are entered into thedigital prosthesis model in a manner matching the already integratedstandard front dental arch shape data.

In a preferred embodiment of the system, it comprises a graphicaldisplay and the data-processing device is adapted to show a graphicalrepresentation of the digital prosthesis model on the display. A digitalwax knife is provided as a program function by the data-processingdevice, in order to allow a user to design the gum and the prosthesisbase surfaces with the digital wax knife in the graphical representationof the digital prosthesis model. The configurations of the gum and theprosthesis base surfaces, which are introduced by the user in thegraphical display using the digital wax knife, are transferred into thedigital prosthesis model by the data-processing device.

In a preferred embodiment of the system, the data-processing device isadapted to provide a multiplicity of predetermined surface textures forselection, and to make these applicable after selection by the user toregions of the surfaces of the digital prosthesis model which have beenselected by the user, and transfer them into the digital prosthesismodel.

In a preferred embodiment of the system, the data-processing device isadapted to call up at least one gingiva parameter for specification, towhich at least one of the following parameters belongs: gingival frameof the tooth lengths of the installed teeth, minimum wall thickness ofupper and lower jaw bases, surface texture parameters of the palatesurface and geometrical parameters of the transition region from theprosthesis base body to the tooth, the data-processing device beingadapted to transfer entered gingiva parameters into the digitalprosthesis model.

In a preferred embodiment of the system, the data-processing device isadapted to call up at least one tooth cavity parameter for specificationby the user, the width of the adhesive gap between the inner wall of thetooth cavity and the inserted tooth base and the position and number ofspacers on the inner wall of the tooth cavity for defined positioning ofthe base of the inserted tooth with a uniformly wide adhesive gapbelonging to the tooth cavity parameters, and to transfer the specifiedtooth cavity parameters for all tooth cavities into the digitalprosthesis model.

In a preferred embodiment of the system, the data-processing device isadapted, during the calculation of the cavities for prefabricatedplastic teeth, to establish whether the remaining wall thickness of theprosthesis base below the cavity would fall below a predeterminedminimum wall thickness, and if so to store the length to which theplastic tooth is to be reduced in order to comply with the predeterminedminimum wall thickness below the cavity, to adapt the cavity to thereduced length of the plastic tooth and to store it in the digitalprosthesis model. Subsequently, the data-processing device may control amilling device with these data in such a way that the prefabricatedplastic tooth is shortened to the stored reduced length of the plastictooth.

In a preferred embodiment of the system, the data-processing device isfurthermore adapted to provide a selection menu for artificial teethmade of different materials, in which a material selection from dentalmaterial is possible for each tooth position, the data-processing devicefurthermore being adapted to take the selected material type intoaccount during the calculation of the cavities in the prosthesis basebodies.

In a preferred embodiment of the system, the bite fork has an inner bitearch and an outer arch, which is applied thereon using articulations andis to be aligned parallel to the Camper plane and parallel to thebipupillar line, whereupon the resulting deviation of the parallelism ofthe inner bite arch relative to the aligned outer arch can be read fromscales on the articulations.

The invention will be described below with the aid of an exemplaryembodiment in the figures, in which:

FIG. 1 shows a plan view of standard impression trays for upper andlower jaw bases, with plastic material therein,

FIG. 2 shows a perspective view of a centric tray for positiondetermination of the upper jaw and lower jaw,

FIG. 3 shows a sampling device for scanning the impressed shapes of theupper and lower jaw bases,

FIG. 4 shows the shapes of the upper and lower jaw bases in a virtualarticulator,

FIG. 5 shows perspective views of the individualized impression traysproduced on the basis of the scanned data of the shapes taken of theupper and lower jaw bases,

FIG. 6 shows a perspective view of an individualized impression trayduring its production in a CAD/CAM-controlled machine on the basis ofthe scanned data of the shapes of the upper and lower jaw bases,

FIG. 7 shows plan views of the finished individualized impression trays,

FIG. 8 shows a view of an individualized impression tray when fillingwith plastic material,

FIGS. 9a )-c) show perspective views of a bite fork, of the bite forkwhen determining the occlusal plane, and a detail view of the bite forkwith a scale for displaying data concerning the position of the occlusalplane,

FIG. 10 shows a perspective view of an individualized impression trayfor the upper jaw during the addition of a selected standard frontdental arch,

FIG. 11 shows a view of the individualized impression trays after thejaw relation determination by means of an incisal pin record,

FIG. 12 shows a representation of the digital prosthesis model duringintegration of the standard front dental arch shape data, called up froma database, of the selected standard front dental arch,

FIG. 13 shows a representation of the digital prosthesis model of thelower jaw base from above,

FIG. 14 shows a perspective detail view of the digital prosthesis modelduring integration of premolar tooth rows, called up from the database,into the digital prosthesis model,

FIG. 15 shows a plan view of the lower jaw of the digital prosthesismodel during the insertion of premolar tooth rows,

FIG. 16 shows a perspective representation of the digital prosthesismodel with integrated tooth shape data of all teeth during thefunctional check of the positioning with a digital articulator,

FIG. 17 shows perspective representations of the digital prosthesismodel during the modelling of the gum by means of a digital wax knife,

FIG. 18 shows a cross-sectional view of the digital prosthesis model inthe region of a tooth cavity of the lower jaw base,

FIG. 19 shows a perspective view of a jaw prosthesis base beingmanufactured with a CAD/CAM manufacturing apparatus controlled on thebasis of the digital prosthesis model,

FIG. 20 shows a schematic view of prefabricated plastic teeth during theautomatically controlled basal adaptation/shortening,

FIG. 21 shows perspective views during the insertion of prosthetic teethinto the prosthesis base,

FIG. 22 shows a perspective view of the inserted dental prosthesisduring the functional and aesthetic check,

FIG. 23 shows a plan view of situation models of the upper and lower jawbases, produced with dental putty gypsum,

FIG. 24 shows a perspective representation of the models of upper andlower jaw bases inserted into an articulator,

FIG. 25 shows a perspective view of the models in the articulator afterproduction of individualized impression trays,

FIG. 26 shows perspective views of the individualized impression trayswhich have been produced, with an interface for receiving the transferbow system,

FIG. 27 shows a perspective view of a transfer bow system for alignmenton the patient;

FIG. 28 shows a perspective view of the transfer bow system positionedon the patient,

FIG. 29 shows a perspective view during the production of the designedtrial body from a block in a CAD/CAM-controlled manufacturing apparatus,

FIG. 30 shows a perspective representation of the CAD/CAM-controlledmanufacturing apparatus during the manufacture of the prosthetic teethon the basis of the data from the digital prosthesis model,

FIG. 31 shows a perspective representation of the prosthetic teethmachined from a block, and

FIG. 32 shows a flow diagram including the steps which are performedwhen using the system according to the invention.

The production of a dental prosthesis using a method and systemaccording to the invention, in which individualized impression trays areused, will first be explained below.

FIG. 1 shows a plan view of standard impression trays 2, 4, with whichthe shapes of the upper and lower jaw bases have been taken with plasticmaterial contained therein. FIG. 2 shows the way in which a firstposition determination of the upper jaw with respect to the lower jawhas been carried out with a centric tray 6 (device for determining theintervestibular relation).

These shapes of the upper and lower jaw bases which have been taken arescanned in a sampling apparatus 8 represented in FIG. 3 and are storedin digitized form in the data-processing device.

FIG. 4 schematically represents the way in which the shapes of the upperand lower jaw bases are positioned in a virtual articulator in thedata-processing device by means of the position determination carriedout, that is to say the chewing movements are simulated in the virtualarticulator after the positioning with the digital prosthesis model.

On the basis of the digital prosthesis model thus initially obtained, ina CAD/CAM-controlled manufacturing apparatus, as represented in FIG. 6,the individualized impression trays 12, 14 are produced from a blank, inthe present example by an ablative milling method. The individualizedimpression trays which are produced are represented in FIG. 5, in whichproduced pins 11, 13 and reception recesses 15, 16 for receivingregistering elements can also be seen.

FIG. 7 shows plan views of the individualized impression trays 12 and 14which have been produced, with registering elements 18 and 20 fastenedthereon.

FIG. 8 shows the way in which an individualized impression tray isfilled with plastic material. The detailed shapes of the upper and lowerjaw bases are taken with the individualized impression trays 12, 14 andplastic material located thereon. The functional movements of thepatient are to be carried out during the impression. The position of theocclusal plane is also determined in this case, to which end a bite forkas represented in FIG. 9a is used. The bite fork 22 has an inner bitearch 24, which is introduced between the individualized impression trays12, 14 during the impression process just mentioned. The inner bite arch24 is connected to an outer arch 26 via articulations, which, with arigidly located inner bite arch 24, make it possible to bring the outerarch 26 parallel to the Camper plane and align the outer arch 26parallel to the bipupillar line. This involves a relative movement ofthe outer arch 26 with respect to the rigidly located bite arch 22,which is made possible by the articulations. The relative position ofthe inner bite arch 24 when the outer arch 26 is aligned can then bemeasured with the aid of the adjustment of the articulations, to whichend each articulation is provided with a scale 30 which shows theadjustment which has been carried out and therefore indicates theposition parameters of the inner bite arch 24 relative to the outer arch26 aligned with the Camper plane and parallel to the bipupillar line.The position parameters which have been read are stored as parameters ofthe occlusal plane.

FIG. 10 schematically represents the way in which, during theimpression, i.e. while the individualized impression trays 12, 14 arelocated in the patient's mouth, a standard front dental arch 40 matchingthe patient is selected from a provided set of upper or lower standardfront dental arches. As a function of the physiological situation, theselected standard front dental arch 40 is positioned on the associatedindividualized impression tray 12 according to the relevantphysiological situation and fastened on the impression tray 12 by afastening means. The fastening means may for example be a wax block,photocuring material which is cured after final positioning, or anadjustable mechanism which is fitted on the individualized impressiontray in a recess provided therefor. In this example, the standard frontdental arch contains six adjacent front teeth; in principle, standardfront dental arches with a different number of front teeth may also beused.

The set of standard front dental arches may, for example, contain frontdental arches with different front tooth sizes (small/medium/large) anddifferent front dental arch sizes (wide/medium/narrow). Each standardfront dental arch may, for example, comprise six front teeth.

FIG. 11 represents the way in which, during the jaw relationdetermination by means of an incisal pin record, the exact vertical andhorizontal position of the upper jaw with respect to the lower jaw isdetermined. This position of the two individualized impression trays isfixed by a suitable material in the patient's mouth. The two connectedimpression trays, with the shapes of the upper and lower jaw bases takenin the plastic material held therein and with a standard front dentalarch fastened on one of the impression trays, are introduced in aconnected, registered bite position into a sampling device 8, forexample as shown in FIG. 3, in order to provide a starting point for thedigital prosthesis model by sampling the shape and digitized storagethereof. The digitized shapes of the upper and lower jaw bases arepositioned with an average value in the determined jaw relation in thevirtual articulator in the data-processing device, as shown in FIG. 10.

If deviations from the zero position of the scales were registeredduring the position determination of the occlusal plane, the deviatingvalues are to be entered into the data-processing device. The positionof the occlusal plane is adapted according to the specifications.

The further construction and refinement of the digital prosthesis modelthen takes place in the data-processing device, which delivers a displayof the spatial digital prosthesis model, as schematically shown in FIG.12.

For the physically selected standard front dental arch, theidentification of which is entered into the data-processing device, adata set of digital standard front dental arch shape data for theselected standard front dental arch is then called up by thedata-processing device from a database. This digital model of theselected standard front dental arch is then integrated into the digitalprosthesis model in such a way that the position of the digital model ofstandard front dental arch shape data which has been called up relativeto the digitized jaw base data matches as well as possible the positionof the scanned data of the standard front dental arch fastened on theimpression tray in the digital prosthesis model. This is indicated inFIG. 12 by showing the digital model 41 of the selected standard frontdental arch relative to the digitized upper jaw base 114 in differentpositions, these positions being varied until the best possiblecorrespondence for the scanned data of the physical standard frontdental arch 40 with respect to the upper jaw base is achieved. As soonas the optimal positioning of the digital model of the selected standardfront dental arch is achieved, this digital model 41 of the selectedstandard front dental arch is integrated into the digital prosthesismodel in the correct relative position with respect to the upper jawbase 114.

The data-processing device is then furthermore adapted to call up anantagonist standard front dental arch, which matches the selectedstandard front dental arch, from the database of the digital models forthe standard front dental arches. If a plurality of antagonist frontdental arches in the database are declared potentially suitable for theselected standard front dental arch, these are shown for selection bythe data-processing device. Subsequently, the digital model data of theselected antagonist standard front dental arch 42 are combined with thedigitized data of the digital prosthesis model of the associated jawbase, in such a way that an optimal setting/position with the alreadypreviously selected digital data of the selected standard front dentalarch 41, which have been integrated into the digital prosthesis model,is achieved. This is represented in FIG. 13, where a matching antagoniststandard front dental arch has been integrated into the lower jaw of thedigital prosthesis model after the positioning of the digital model ofthe selected standard front dental arch 41 for the upper jaw has alreadytaken place in FIG. 12.

FIG. 15 shows a schematic plan view from above of the lower jaw base 112of the digital prosthesis. The digital standard front dental arch shapedata 42 are already integrated therein. The data-processing device isnow adapted to call up, from the database, one or more, if there areseveral, premolar tooth rows 44 declared as matching the alreadyintegrated standard front dental arch in the database. When there are aplurality of possible premolar tooth rows, these are offered by thedata-processing device to the user for selection. After selection, thedigital model data of the selected premolar tooth row are called up fromthe database and entered into the jaw base data of the digitalprosthesis, while taking into account the occlusal plane, the positionof which has already been determined. FIG. 14 shows a lateral point ofcontact of the premolar tooth row with the front dental arch, only thelast tooth lying at the contact point from the premolar tooth row andthe front dental arch being shown in each case.

Thus, the tooth data of all teeth are successively entered in theirposition into the digital prosthesis. A functional check of thepositioning is carried out with the digital articulator. Thedata-processing device is in this case adapted to detect and storefunctional contact defects in the occlusion and in the occlusionmovement. Contact defects can subsequently be removed by the user usinggrinding technology.

As shown in FIG. 17, a graphical representation of the digitalprosthesis model is shown by the data-processing device in accordancewith the specifications of the jaw base data and the tooth installation,as represented in FIG. 17, top. The data-processing device furthermoreprovides a so-called “digital wax knife” as a program function. Withthis, a user can configure the shape of the gum in the graphicalrepresentation by the digital wax knife generating the desiredconfiguration in the graphical representation. The desired configurationof the gum 116 is shown in the lower representation in FIG. 17. The gumconfiguration generated in this way by the user is transferred into thedigital prosthesis model.

Furthermore, a multiplicity of predetermined surface textures areprovided by the data-processing device for selection, which the user canselect and apply to selected regions of the surfaces of the digitalprosthesis model, after which they are transferred into the digitalprosthesis model.

For further configuration of the gingiva, a number of gingiva parametersare offered by the data-processing device to the user for specification.These include:

1. gingival frame of the tooth lengths of the installed teeth, i.e. thedepth of the cavity which receives the tooth base in the jaw base,

2. minimum wall thickness of upper and lower jaw bases, i.e. the minimumthickness of the wall thickness of the base remaining below a cavity,

3. surface texture parameters of the palate surface, and

4. geometrical parameters of the transition region from the prosthesisbase body to the tooth in the cavity. With the latter geometricalparameters, the user can configure the transition region from theprosthesis base surface to a cavity, and may for example providerounding.

By rounding or chamfering on the upper edge, the cavity is widenedslightly on the upper edge. This creates a slightly widened edge aroundthe tooth base in the transition region to the prosthesis base surface,this widened transition region being filled with adhesive when adhesivebonding of the artificial teeth. When antibacterial additives are usedin the adhesives, improved protection against ingress or establishmentof bacteria in the transition region of the tooth base and tooth cavityof the prosthesis base can thus be ensured.

It is necessary to take into account and comply with a minimum wallthickness of the upper and lower jaw bases in the region of the cavitiesin order to ensure a minimum strength of the prosthesis base body in theregion of the cavities as well.

Furthermore, tooth cavity parameters are called up by thedata-processing device for specification by the user. These includepositioning, number and size of spacers 124 in a cavity 120, as shown inFIG. 18. These spacers 124 on the inner walls of the cavity 120 ensurethat the tooth base 142 of an artificial tooth 140 inserted into thecavity 120 is held reliably positioned in the cavity 120, whilesimultaneously a defined intermediate space remains between the outersurface of the tooth base 142 and the inner wall of the cavity 120, sothat a defined intermediate space for receiving adhesive is provided. Inthis way, a uniformly wide adhesive gap around the tooth base 142 in thecavity 120 is obtained when positioning the artificial tooth in thecavity of the prosthesis base. In principle, the width of the adhesivestrip may also belong to the tooth cavity parameters to be specified.The specified tooth cavity parameters are then transferred for all toothcavities into the digital prosthesis model.

When, during the calculation of the cavities, it is established in thedata-processing device that the remaining wall thickness of theprosthesis base below the cavity would fall below the predeterminedminimum wall thickness, for the artificial tooth provided for saidcavity the data-processing device stores a shortened length such thatthe predetermined minimum wall thickness below the cavity is maintained.In the case of using prefabricated plastic teeth, the prefabricatedplastic tooth length to be shortened is then used to control anautomatic milling apparatus, into which the prefabricated plastic toothis inserted and is shortened to the shortened length. This process isschematically shown in FIG. 20.

After all the data and parameters in the digital prosthesis model havebeen specified and established, the data-processing device controls aCAD/CAM-controlled manufacturing machine in accordance with this digitalprosthesis model, for example a milling machine in which the designedprosthesis base body is produced from a block consisting of gum-colouredplastic material by an ablative method, the processing of the prosthesisbase body with an automatically controlled miller being shown in FIG.19. As an alternative, the manufacture of the prosthesis base bodies mayalso be carried out by a constructive method.

Subsequently, the prosthetic teeth are adhesively bonded into thecavities of the manufactured prosthesis base bodies by means of ajoining medium, as shown in FIG. 21.

In order to adhesively bond the artificial teeth permanently in thecavities, correct positioning is necessary. In this case, each tooth oreach tooth group is to be checked individually and manually onto thecorrect recess in the cavity and subsequently adhesively bonded. As thechecking instrument, a transfer template is to be used, which mayadditionally be used as a transfer instrument when adhesively bondingthe individual teeth and/or tooth row. This transfer template is anegative mould of the tooth group, produced by a CAD/CAM manufacturingmachine. Reliable and correct positioning is thus ensured. The teethand/or tooth groups are positioned in the template and transferred intothe cavities of the prosthesis base body during the adhesive bonding.The final polishing is carried out conventionally on a polishing unit.The prosthesis base bodies must be smooth and free of burrs, and theprosthesis edges are to be processed round and never with sharp edges.

FIG. 22 illustrates the functional and aesthetic check of themanufactured partial prosthesis in the patient's mouth.

FIG. 32 shows a flow chart with steps which may be employed when usingthe system according to the invention. In the left-hand branch, thesteps according to the procedure described so far with the aid of FIGS.1 to 22 are carried out, numbers which correspond to the numbers ofFIGS. 1 to 22 illustrating these steps in the preceding description ofthe figures being indicated on the blocks of the process steps. Thesteps 23 to 30 listed in the right-hand branches are optionallyadditional or alternatively possible steps within the process, which maybe carried out on the process steps represented. These steps 23 to 30will be described below with the aid of FIGS. 23 to 30 illustratingthese steps.

FIG. 23 shows the situation models which are produced. Production iscarried out in a standard way with class 3 dental gypsum.

As shown in FIG. 24, the models of the upper and lower jaw bases areplaced with an average value in the articulator. Positioning of upperjaw and lower jaw is possible with the position determination carriedout by means of a centric tray.

As shown in FIG. 25, an individualized impression tray is produced fromphotocuring or autopolymerizing tray material on the basis of theinformation obtained in this way. The registering elements are directlypolymerized in during this.

As shown in FIG. 26, a holder/interface for the registering articulationto the skull/articulation-related allocation of the upper and lower jawbases is provided on the registering element 18 of the individualizedimpression tray 12. As an alternative, the registering element itselfmay be replaced.

FIG. 27 shows a transfer bow system. When the transfer bow system isaligned on the patient, the adjustment screws on the registeringarticulation are fixed. FIG. 28 shows the situation during adjustment onthe patient.

The individual position of the registering articulation is digitized byscanning. The placement position of the patient's upper and lower jawbases can be reproduced individually in the virtual articulator.

FIG. 29 represents the way in which the designed trial body ismanufactured by the ablative method from a block in a CAD/CAM-controlledmanufacturing machine. The prosthetic teeth are subsequentlyprovisionally adhesively bonded in the cavities.

As an alternative, the entire trial prosthesis (prosthesis base bodyincluding prosthetic teeth) may be manufactured in one piece.

The functional and aesthetic check of the trial prosthesis is carriedout in the patient's mouth.

After the trial, optionally correction of the tooth position/placementand optionally new digitization in the sampling device and storage ofthe modified situation in the data-processing device are carried out.

After the correction, the permanent dental prosthesis or a further trialbody may be manufactured.

In a CAD/CAM manufacturing machine controlled by the data-processingdevice, the artificial teeth are manufactured in accordance with thedigital prosthesis model by ablative or constructive methods, anablative method being illustrated in FIG. 30. The prosthetic teethmachined from a block, and still connected to the block via supportingwebs, are represented in FIG. 31.

The gingiva parameters defined in the data-processing device are takeninto account automatically during the manufacture of the prostheticteeth. Retrospective reduction of the tooth lengths is not necessary inthis method.

LIST OF REFERENCES

2, 4 standard impression tray

6 centric tray

8 sampling device

10 virtual articulator

12, 14 individualized impression tray

11, 13 pin for attaching registering elements

15, 16 holders for inserting registering elements

18, 20 registering elements

22 bite fork

24 inner bite arch

26 outer arch

28 articulations of the bite fork

30 scale of the bite fork

40 standard front dental arch

41 digital standard front dental arch shape data

42 digital antagonist standard front dental arch shape data

44 digital premolar tooth row shape data

112 lower jaw base in the digital prosthesis model

114 upper jaw base in the digital prosthesis model

116 gum in the digital prosthesis model

120 cavity

124 spacer

140 artificial tooth

142 tooth base

1. A system for the construction of a total dental prosthesis,comprising an upper, lower or set of upper and lower standard frontdental arch(es) (40), one or more standard impression tray(s) (2, 4) orindividualized impression tray(s) (12, 14) for taking shapes of theupper and/or lower jaw bases with plastic material, a fastening meansfor fastening the upper, lower or set of upper and lower standard frontdental arch(es) to the one or more standard or individualized impressiontrays, a scanner for scanning an impression of the upper, lower or upperand lower jaw bases, a memory for storing the scanned impression as adigital prosthesis model, and a manufacturing apparatus for producingthe upper and/or lower jaw prosthesis bases from dental materialsaccording to the digital prosthesis model.
 2. The system for theconstruction of a total dental prosthesis according to claim 1, furthercomprising a bite fork (22) for acquiring the position of an occlusalplane by alignment parallel to a bipupillar line and a Camper plane whentaking the shapes of the upper and lower jaw bases, and wherein thememory is further configured for storing the digitized position of theocclusal plane relative to the upper and lower jaw bases, wherein themanufacturing apparatus produces the upper and lower jaw prosthesisbases by ablative or constructive methods under the control of adata-processing device.
 3. The system for the construction of a totaldental prosthesis according to claim 2, wherein the scanner isconfigured to digitize and store impressions of the upper and lower jawbases in order to form a starting point for the digital prosthesis modelto provide scanned data.
 4. The system for the construction of a totaldental prosthesis according to claim 3, comprising a database whichcontains digital standard front dental arch shape data (41) for allstandard front dental arches, wherein the data-processing device isconfigured to retrieve the standard front dental arch shape data, andwherein the data-processing device is configured to integrate theretrieved standard front dental arch shape data with the scanned data ofimpressions to provide a digital prosthesis model.
 5. A system accordingto claim 4, wherein the data-processing device is configured to retrievea matching antagonist standard front dental arch from the database inthe form of digital antagonist standard front dental arch shape data(42) and combine it with the data of the digital prosthesis model, insuch a way that an optimal match with the selected standard front dentalarch is achieved.
 6. A system according to claim 5, wherein thedata-processing device is configured, after integration of the standardfront dental arch shape data (41) and optionally antagonist standardfront dental arch shape data (42) into the digital prosthesis model, tooffer one or more premolar tooth rows matching the selected standardfront dental arch for selection and, after selection, wherein thedata-processing device is configured to retrieve premolar tooth rowshape data (44) and enter the premolar tooth row shape data (44) intothe digital prosthesis model.
 7. A system according to claim 6, whereinthe data-processing device is configured to generate a graphicalrepresentation of the digital prosthesis model on a display and toprovide a digital wax knife as a program function, in order to allow auser to design the gum and the prosthesis base surfaces with the digitalwax knife in the graphical representation of the digital prosthesismodel, and to transfer the configurations carried out into the digitalprosthesis model.
 8. A system according to claim 7, wherein thedata-processing device is configured to provide a multiplicity ofpredetermined surface textures for selection, and to make the surfacetextures applicable to selected regions of the surfaces of the digitalprosthesis model and transfer them into the digital prosthesis model. 9.A system according to claim 8 wherein the data-processing device isconfigured to retrieve at least one gingiva parameter for specification,to which at least one of the following gingiva parameters belongs:gingival frame of the tooth lengths of the installed teeth, minimum wallthickness of upper and lower jaw bases, surface texture parameters ofthe palate surface and geometrical parameters of the transition regionfrom the prosthesis body to the tooth, wherein the data-processingdevice is configured to transfer entered gingiva parameters into thedigital prosthesis model.
 10. A system according to claim 9, wherein thedata-processing device is configured to call up at least one toothcavity parameter for specification, to which a width of an adhesive gapbetween an inner wall of the tooth cavity and an inserted tooth base andthe position and number of spacers on the inner wall of the tooth cavityfor defined positioning of the base of the inserted tooth with auniformly wide adhesive gap relative to the inner surfaces of the toothcavity belong, and to transfer the specified tooth cavity parameters forall tooth cavities into the digital prosthesis model.
 11. A systemaccording to claim 10, wherein the data-processing device is configured,when, during the calculation of the cavities for prefabricated plasticteeth, it is established that the remaining wall thickness of theprosthesis base below the cavity would fall below a predeterminedminimum wall thickness, to store the length to which the plastic toothis to be reduced in order to comply with the predetermined minimum wallthickness below the cavity, to adapt the cavity to the reduced length ofthe plastic tooth and to store it in the digital prosthesis model, andto control a milling device in such a way that the prefabricated plastictooth is shortened to the stored reduced length of the plastic tooth.12. A system according to claim 11, wherein the data-processing deviceis configured to provide a selection menu for artificial teeth made ofdifferent materials, in which a material selection from dental materialsis possible for each tooth position, the data-processing device beingconfigured to take the selected material type into account during thecalculation of the cavities in the prosthesis bases, in order in eachcase to obtain an optimally dimensioned adhesive gap for the respectivematerial type.
 13. A system according to claim 12, wherein the bite fork(22) has an inner bite arch (24) and an outer arch (26) applied thereonusing articulations, the articulations being provided with scales (30)so that, after turning the outer arch into alignment parallel to theCamper plane and parallel to the bipupillar line, the resultingdeviation of the parallelism of the inner bite arch from that of thealigned outer arch can be read from the scales on the articulations.